CN103680386A

CN103680386A - GOA circuit and displaying device for panel display

Info

Publication number: CN103680386A
Application number: CN201310700124.6A
Authority: CN
Inventors: 虞晓江; 李文英; 李长晔; 赖梓杰
Original assignee: Shenzhen China Star Optoelectronics Technology Co Ltd
Current assignee: TCL China Star Optoelectronics Technology Co Ltd
Priority date: 2013-12-18
Filing date: 2013-12-18
Publication date: 2014-03-26
Anticipated expiration: 2033-12-18
Also published as: US20160253938A1; WO2015089917A1; CN103680386B; US9530371B2

Abstract

The invention relates to a GOA circuit and a displaying device for panel display. The GOA circuit comprises multiple cascaded GOA units. Each GOA unit comprises a pull-up control circuit (400) and a downlink circuit (500). Each downlink circuit (500) comprises a first thin film transistor (T22), wherein a grid electrode of the first thin film transistor is connected with a grid electrode signal point (Q(n)). Clock signals (CK(n)) are input to a drain electrode and a source electrode respectively and the drain electrode and the source electrode respectively output a booting signal ST(n). Each pull-up control circuit (400) comprises a second thin film transistor (T11) and a third thin film transistor (T12). A booting signal (ST(n-2)) is input to a grid electrode of the second thin film transistor (T11) and a drain electrode and a source electrode of the second thin film transistor (T11) are connected with a horizontal scanning line (G(n-2)) and a grid electrode signal point (Q(n)) respectively. A grid electrode of the third thin film transistor (T12) is connected with a horizontal scanning line (G(n-1)) and a drain electrode and a source electrode of the third thin film transistor (T12 ) are connected with the horizontal scanning line (G(n-1)) and a grid electrode signal point (G(n)) respectively. The invention further provides the corresponding displaying device. The stability of the GOA circuit and the relevant displaying device under the high temperature can be improved.

Description

GOA circuit and display device for flat pannel display

Technical field

The present invention relates to technical field of flat panel display, relate in particular to a kind of GOA(Gate Driver on Array for flat pannel display, the capable driving of array base palte) circuit and display device.

Background technology

The driving of current active panel display board horizontal scanning line is mainly completed by the external IC of panel, the charging and discharging step by step of the horizontal scanning line that external IC is can control panel pixels at different levels (pixel) connected.And GOA technology, be the capable driving of Gate Driver on Array(array base palte) technology, can use original processing procedure of panel display board that the driving circuit of horizontal scanning line is produced on the substrate around of viewing area, make it to replace external IC to complete the driving of horizontal scanning line.GOA technology can be simplified the production process of display panel, save IC binding (bonding) technique of horizontal scanning line direction, have an opportunity to promote production capacity and reduce costs, and the integrated level that can promote panel display board makes it to be more suitable for making the demonstration product of narrow frame or Rimless.

Existing GOA circuit, generally includes a plurality of GOA unit of cascade, the corresponding one-level horizontal scanning line that drives in every one-level GOA unit.The primary structure of GOA unit comprises pull-up circuit (Pull-up part), pull-up control circuit (Pull-up control part), under the road (Transfer Part) that conducts electricity, pull-down circuit (Key Pull-down Part) and drop-down holding circuit (Pull-down Holding Part), and the bootstrapping of responsible current potential lifting (Boast) electric capacity.Pull-up circuit is mainly responsible for clock signal (Clock) to be output as grid (Gate) signal; Pull-up control circuit is responsible for controlling the opening time of pull-up circuit, generally connect that earlier stages GOA circuit passes under the number of delivering a letter or Gate signal; Pull-down circuit is responsible in the very first time, Gate being dragged down as electronegative potential, closes Gate signal; Drop-down holding circuit is responsible for the Gate signal of Gate output signal and pull-up circuit (being commonly referred to Q point) to maintain (Holding) (being negative potential) in off position, conventionally has two drop-down module alternating actions that maintain; Bootstrap capacitor (C boast) is responsible for the secondary lifting that Q is ordered, and is conducive to like this G (N) output of pull-up circuit.

The object of GOA circuit is exactly that the sweep waveform of integrated circuit output is exported by the mode of circuit operation, can be to tin indium oxide (ITO) electrode input data signal thereby pixel switch is opened.Data-signal after having inputted maintains data-signal content until the unlatching of next frame.In circuit operation process, because of a sweep circuit, to open and at a frame, in the remaining time, all close later, it is long more a lot of than sweep time that sweep circuit cuts out (maintenance) time, the thin film transistor (TFT) in GOA circuit stablized to particular requirement very high.The high-temperature stability of GOA circuit is one of key factor affecting the application of GOA technology.Under high temperature, the electric leakage that forms the thin film transistor (TFT) of GOA circuit becomes large, and the output waveform of GOA circuit may occur extremely.

Summary of the invention

Therefore, the object of the present invention is to provide a kind of GOA circuit for flat pannel display, reduce the impact of thin film transistor (TFT) electric leakage on the output of GOA circuit under high temperature, promote the high-temperature stability of GOA circuit output.

Another object of the present invention is to provide a kind of display device of applying above-mentioned GOA circuit, reduce the impact of thin film transistor (TFT) electric leakage on the output of GOA circuit under high temperature, promote the high-temperature stability of GOA circuit output.

For achieving the above object, the invention provides a kind of GOA circuit for flat pannel display, a plurality of GOA unit that comprises cascade, according to n level GOA unit controls, viewing area n level horizontal scanning line is charged, this n level GOA unit comprises pull-up circuit, pull-down circuit, drop-down holding circuit, pull-up control circuit, under conduct electricity road and bootstrap capacitor; This pull-up circuit, pull-down circuit, drop-down holding circuit and bootstrap capacitor are connected with this n level horizontal scanning line with signal point respectively, this pull-up control circuit with under the road that conducts electricity be connected with this signal point respectively;

The road that conducts electricity under this comprises:

The first film transistor, its grid connects this signal point, and drain electrode and source electrode are inputted respectively n level clock signal and output actuation signal;

This pull-up control circuit comprises:

The second thin film transistor (TFT), its grid input is from the actuation signal of n-2 level GOA unit, and drain electrode is connected respectively n-2 level horizontal scanning line and this signal point with source electrode;

The 3rd thin film transistor (TFT), its grid connects n-1 level horizontal scanning line, and drain electrode is connected respectively this n-1 level horizontal scanning line and this signal point with source electrode.

Wherein, this drop-down holding circuit comprises:

The 4th thin film transistor (TFT), its grid connects the first circuit point, and drain electrode is connected respectively this n level horizontal scanning line and input the first DC low-voltage with source electrode;

The 5th thin film transistor (TFT), its grid connects second circuit point, and drain electrode is connected respectively this n level horizontal scanning line and this first DC low-voltage of input with source electrode;

The 6th thin film transistor (TFT), its grid connects this first circuit point, and drain electrode is connected respectively this n-1 level horizontal scanning line and this signal point with source electrode;

The 7th thin film transistor (TFT), its grid connects this second circuit point, and drain electrode is connected respectively this n-1 level horizontal scanning line and this signal point with source electrode;

The 8th thin film transistor (TFT), its grid connects this signal point, and drain electrode is connected respectively this first circuit point and this first DC low-voltage of input with source electrode;

The 9th thin film transistor (TFT), its grid connects this signal point, and drain electrode is connected respectively this second circuit point and inputs this first DC low-voltage with source electrode;

The tenth thin film transistor (TFT), its grid is inputted the first clock signal, and drain electrode is inputted respectively this first clock signal and is connected this first circuit point with source electrode;

The 11 thin film transistor (TFT), its grid input second clock signal, drain electrode is inputted respectively this first clock signal and is connected this first circuit point with source electrode;

The 12 thin film transistor (TFT), its grid is inputted this second clock signal, and drain electrode is inputted respectively this second clock signal and is connected this second circuit point with source electrode;

The 13 thin film transistor (TFT), its grid is inputted this first clock signal, and drain electrode is inputted respectively this second clock signal and is connected this second circuit point with source electrode;

During work, the frequency of this first clock signal and this second clock signal is lower than this n level clock signal, and this first circuit point is alternately subject to this first clock signal with this second clock signal charging and in noble potential with this second circuit point.

Wherein, this pull-up circuit comprises: the 14 thin film transistor (TFT), and its grid connects this signal point, and drain electrode is inputted respectively this n level clock signal and is connected this n level horizontal scanning line with source electrode.

Wherein, this pull-down circuit comprises: the 15 thin film transistor (TFT), and its grid connects n+2 level horizontal scanning line, and drain electrode is connected respectively this n level horizontal scanning line and this DC low-voltage of input with source electrode; The 16 thin film transistor (TFT), its grid connects this n+2 level horizontal scanning line, and drain electrode is connected respectively this signal point and inputs this DC low-voltage with source electrode.

Wherein, the dutycycle of this n level clock signal is less than 50%.

Wherein, the dutycycle of this n level clock signal is 40%.

Wherein, this first clock signal is inputted a plurality of GOA unit of described cascade by public metal wire.

Wherein this second clock signal is inputted a plurality of GOA unit of described cascade by public metal wire.

Wherein, this DC low-voltage is inputted a plurality of GOA unit of described cascade by public metal wire.

The present invention also provides a kind of display device, and it comprises the GOA circuit for flat pannel display as above.

The present invention can promote GOA circuit and related display apparatus stability at high temperature for the GOA circuit of flat pannel display, and reduces the capacitance-resistance delay (RC delay) of GOA charging signals.Use GOA circuit of the present invention can make the flat panel display product of narrow frame cheaply or Rimless.

Accompanying drawing explanation

Below in conjunction with accompanying drawing, by the specific embodiment of the present invention is described in detail, will make technical scheme of the present invention and other beneficial effects apparent.

In accompanying drawing,

Fig. 1 is that the present invention is for the circuit diagram of GOA circuit (single-stage) embodiment of flat pannel display;

Fig. 2 output waveform schematic diagram 80 ℃ time that is the present invention for the GOA circuit of flat pannel display;

Fig. 3 is that the present invention is for the multistage architecture schematic diagram of the GOA circuit of flat pannel display;

Fig. 4 has applied the structural representation of the present invention for the panel display apparatus of the GOA circuit of flat pannel display.

Embodiment

Referring to Fig. 1, it is the circuit diagram of the present invention for GOA circuit (single-stage) embodiment of flat pannel display.GOA circuit of the present invention can comprise a plurality of GOA unit of cascade, according to n level GOA unit controls, viewing area n level horizontal scanning line G (n) is charged, this n level GOA unit comprises pull-up circuit 100, pull-down circuit 200, drop-down holding circuit 300, pull-up control circuit 400, under conduct electricity road 500 and bootstrap capacitor Cb; This pull-up circuit 100, pull-down circuit 200, drop-down holding circuit 300 and bootstrap capacitor Cb respectively with signal point Q(n) with this n level horizontal scanning line G(n) be connected, this pull-up control circuit 400 with under conduct electricity road 500 respectively with this signal point Q(n) be connected.

This pull-up circuit 100 comprises: directly control the thin film transistor (TFT) T21 charging to viewing area n level horizontal scanning line G (n), its grid connects this signal point (Q(n)), the drain electrode of T21 is inputted respectively this n level clock signal C K(n with source electrode) be connected this n level horizontal scanning line G(n), the current potential of T21 grid Q (n) can directly affect CK (n) G (n) is charged.

Pull-down circuit 200 is included in the cluster film transistor discharging when G (n) charging finishes, and comprises the T31 that G (n) is discharged and the T41 that Q (n) is discharged; T31 grid connects n+2 level horizontal scanning line G(n+2), drain electrode is connected respectively this n level horizontal scanning line G(n with source electrode) and input direct-current low-voltage VSS; T41 grid connects this n+2 level horizontal scanning line G(n+2), drain electrode is connected respectively signal point Q(n with source electrode) and input direct-current low-voltage VSS; T31 and T41 can open during in noble potential and discharge at G (n+2).

Under the road 500 that conducts electricity comprise thin film transistor (TFT) T22, its grid connects this signal point Q(n), drain electrode and source electrode are inputted respectively n level clock signal C K(n) and export actuation signal ST (n);

Pull-up control circuit 400 comprises: thin film transistor (TFT) T11, and its grid input is from the actuation signal ST (n-2) of n-2 level GOA unit, drain electrode is connected respectively n-2 level horizontal scanning line (G(n-2) with source electrode) and this signal point (Q(n)); Thin film transistor (TFT) T12, its grid connects n-1 level horizontal scanning line G(n-1), drain electrode is connected respectively this n-1 level horizontal scanning line G(n-1 with source electrode) and this signal point Q(n).In GOA circuit at different levels of the present invention, increased by 1 thin film transistor (TFT) T12 to Q (n) charging, in order to make up the electric leakage of Q (n) before bootstrapping, kept comparatively stablely before making Q (n) at high temperature boot.

Thin film transistor (TFT) T11, T12 and T22 can control the actuation signal ST of prime GOA circuit is passed to GOA circuit at the corresponding levels, and GOA circuit can be discharged and recharged step by step.

The capacitor C b that has bootstrapping function connecting between Q (n) and G (n), can be when G (n) current potential promotes coupling effect by Cb Q (n) current potential is promoted, thereby the capacitance-resistance that obtains higher Q (n) current potential and less GOA charging signals postpones (RC delay).

The cluster film transistor that drop-down holding circuit (300) comprises can keep in the non-charging of GOA circuit the electronegative potential of G (n) and Q (n) period.This drop-down holding circuit (300) comprising: thin film transistor (TFT) T32, and its grid connects the first circuit point P, drain electrode is connected respectively G(n with source electrode) and input the first DC low-voltage VSS; Thin film transistor (TFT) T33, its grid connects second circuit point K, drain electrode is connected respectively G(n with source electrode) and input the first DC low-voltage VSS; Thin film transistor (TFT) T42, its grid connects the first circuit point P, drain electrode is connected respectively G(n-1 with source electrode) and signal point Q(n); Thin film transistor (TFT) T43, its grid connects second circuit point K, drain electrode is connected respectively G(n-1 with source electrode) and signal point Q(n); Thin film transistor (TFT) T52, its grid connects signal point Q(n), drain electrode is connected respectively the first circuit point P and input the first DC low-voltage VSS with source electrode; Thin film transistor (TFT) T62, its grid connects signal point Q(n), drain electrode is connected respectively second circuit point K and input the first DC low-voltage VSS with source electrode; Thin film transistor (TFT) T53, its grid input low-frequency clock signal ECK, drain electrode is inputted respectively low-frequency clock signal ECK and is connected the first circuit point P with source electrode; Thin film transistor (TFT) T54, its grid input low-frequency clock signal EXCK, drain electrode is inputted respectively low-frequency clock signal ECK and is connected the first circuit point P with source electrode; Thin film transistor (TFT) T63, its grid is inputted this low-frequency clock signal EXCK, and drain electrode is inputted respectively low-frequency clock signal EXCK and is connected second circuit point K with source electrode; Thin film transistor (TFT) T64, its grid input low-frequency clock signal ECK, drain electrode is inputted respectively low-frequency clock signal EXCK and is connected second circuit point K with source electrode;

During work, the frequency of low-frequency clock signal ECK and low-frequency clock signal EXCK is lower than high frequency clock signal CK(n), and this first circuit point P and this second circuit point K are charged by low-frequency clock signal ECK and low-frequency clock signal EXCK alternately and in noble potential, thereby alternately control opening of thin film transistor (TFT) T32 & T42 or T33 & T43, to maintain G (n) or Q (n) at the non-charging electronegative potential in period.Thin film transistor (TFT) T54 and T64 can alternately open to P point or the electric discharge of K point according to the current potential of low-frequency clock signal EXCK and ECK, can better guarantee the alternation of T32 & T42 and T33 & T43, in order to avoid thin film transistor (TFT) to be subject to for a long time the impact of grid voltage stress, improve the operation lifetime of GOA circuit.Thin film transistor (TFT) T52 connects P point and DC low-voltage Vss, thin film transistor (TFT) T62 connects K point and DC low-voltage Vss, T52 and T62 can open during in noble potential at Q (n) and close T32, T42, T33 and T43, make it not affect Q (n) and G (n) charging.

GOA circuit of the present invention becomes more stable before can making to control and at high temperature booting to Q (n) voltage of the film crystal tube grid of horizontal scanning line charging, and the capacitance-resistance of therefore having an opportunity to promote the high-temperature stability of GOA circuit and reducing GOA charging signals postpones (RC delay).Specifically: 1, for maintaining Q (n), at the thin film transistor (TFT) T42 of non-charging current potential in period and the method for attachment of T43, can reduce the electric leakage before Q (n) at high temperature boots; 2, in GOA circuit at different levels, increased by 1 thin film transistor (TFT) to Q (n) charging, in order to make up the electric leakage of Q (n) before bootstrapping.

Referring to Fig. 2, its for the present invention for the GOA circuit of flat pannel display the output waveform schematic diagram 80 ℃ time, wherein the dutycycle of high frequency clock signal CK (n) (duty ratio) is less than 50%, is specially 40%.In Fig. 2, t1～t4 is the setup time before G (n) charging, and t4～t5 is the duration of charging of G (n), and G after t5 (n) is discharged.It is identical that low-frequency clock signal ECK and low-frequency clock signal EXCK can be chosen as frequency, single spin-echo.Can understand Fig. 2 in conjunction with Fig. 1, during t1, the current potential of CK (n-2) starts lifting, and the current potential of G (n-2) and ST (n-2) also and then starts lifting, and thin film transistor (TFT) T11 opens to Q (n) and charges.During t2, the current potential of CK (n-1) starts lifting, and thin film transistor (TFT) T12 also opens to Q (n) and charges.After the lifting of Q (n) current potential, can open thin film transistor (TFT) T52 and T62, thereby close T32, T42, T33 and T43, make it not affect Q (n) and G (n) charging.During t3, the current potential of CK (n-2) starts to decline, and the current potential of G (n-2) and ST (n-2) and then declines, and thin film transistor (TFT) T11 has certain electric leakage and causes the current potential of Q (n) to have certain reduction.But in GOA circuit at different levels of the present invention, increased by 1 thin film transistor (TFT) T12 to Q (n) charging, in order to make up the electric leakage of Q (n) before bootstrapping, kept comparatively stablely before making Q (n) at high temperature boot.During t4, the current potential of CK (n) starts lifting, and thin film transistor (TFT) T21 and T22 open, and Q (n) bootstrapping is to noble potential more and control that T21 charges to G (n) and T22 charges to ST (n).Because the initial lifting time t2 of G (n-1) current potential will be early than the initial lifting time t4 of G (n) current potential, the circuit structure that the drain electrode of T42 and T43 is connected to G (n-1) does not show with respect to the drain electrode of T42 and T43 being connected to the second DC low-voltage Vss2(figure) circuit structure can lower Q (n) before bootstrapping by the electric leakage of thin film transistor (TFT) T42 and T43.After Q (n) bootstrapping, P point and K point current potential are dragged down, and T42 and T43 are closed, and Q (n) electric leakage can be effectively controlled.During t5, CK (n) starts to decline, and Q (n) current potential is not dragged down immediately, and thin film transistor (TFT) T21 and T22 still keep conducting in the short time after t5, and G (n) and ST (n) current potential are dragged down.After this, the lifting of G (n+2) current potential, thin film transistor (TFT) T31 and T41 open, and guarantee that G (n) and Q (n) are pulled to electronegative potential.After this, T52 and T62 close, and T32 & T42 or T33 & T43 can alternately open, to maintain G (n) or Q (n) at the non-charging electronegative potential in period.Therefore in sum, the present invention can make the voltage before GOA circuit Q (n) at high temperature boots more stable, has an opportunity to obtain Q (n) voltage in higher charging period and the capacitance-resistance of less GOA charging signals postpones (RC delay).

Referring to Fig. 3, it is the multistage architecture schematic diagram of the present invention for the GOA circuit of flat pannel display.Fig. 3 has provided a kind of multistage method of attachment of GOA circuit of the present invention, the metal wire of 4 high frequency clock signals of low-frequency clock signal ECK and EXCK, DC low-voltage Vss, CK1～CK4 is positioned over the periphery of GOA circuit at different levels, GOA circuit at different levels (its inner connection referring to Fig. 1) connect 1 CK signal in CK1～CK4, G (n-2) and G (n-1) that ST (n-2), (n-1) level GOA circuit produce, the G (n+2) that (n+2) level GOA circuit produces of n-2 level GOA circuit generation, and produce G (n) and ST (n) signal.Method of attachment shown in Fig. 3 can guarantee that the actuation signal ST (n) of GOA circuit can transmit step by step, makes the horizontal scanning lines at different levels can be by charging and discharging step by step.GOA unit for first and end cascade can adopt the mode of input activation signal to replace the signal input lacking.

GOA circuit of the present invention can use original processing procedure of panel display board to be produced on the substrate around of viewing area, makes it to substitute the driving that external IC completes panel display board horizontal scanning lines at different levels.The present invention is especially applicable to making the flat panel display product of narrow frame or Rimless.

Referring to Fig. 4, it is to have applied the structural representation of the present invention for the panel display apparatus of the GOA circuit of flat pannel display.In Fig. 4, panel display apparatus has display base plate 10, the driving control panel 20 of display base plate 10 tops drives and control signal for display base plate 10 provides, display base plate 10 left area 30 and region, the right 40 have made GOA circuit, can be from the horizontal scanning line of the left side and the right both direction driving viewing area 50.The control signal that GOA circuit is accepted to drive the input signal of control panel 20 and produced step by step horizontal scanning line, the pixel that can control in viewing area 50 is opened line by line.

In sum, the present invention can promote GOA circuit (high frequency clock signal that adopts duty ratio to be less than 50%) and related display part stability at high temperature, and reduces the capacitance-resistance delay (RC delay) of GOA charging signals.Use GOA circuit of the present invention can make the flat panel display product of narrow frame cheaply or Rimless.

The above; for the person of ordinary skill of the art; can make other various corresponding changes and distortion according to technical scheme of the present invention and technical conceive, and all these changes and distortion all should belong to the protection domain of the accompanying claim of the present invention.

Claims

1. the GOA circuit for flat pannel display, it is characterized in that, a plurality of GOA unit that comprises cascade, according to n level GOA unit controls, viewing area n level horizontal scanning line (G (n)) is charged, this n level GOA unit comprises pull-up circuit (100), pull-down circuit (200), drop-down holding circuit (300), pull-up control circuit (400), under conduct electricity road (500) and bootstrap capacitor (Cb); This pull-up circuit (100), pull-down circuit (200), drop-down holding circuit (300) and bootstrap capacitor (Cb) respectively with signal point (Q(n)) with this n level horizontal scanning line (G(n)) be connected, this pull-up control circuit (400) with under conduct electricity road (500) respectively with this signal point (Q(n)) be connected;

The road (500) that conducts electricity under this comprising:

The first film transistor (T22), its grid connects this signal point (Q(n)), drain electrode and source electrode are inputted respectively n level clock signal (CK(n)) and output actuation signal (ST (n));

This pull-up control circuit (400) comprising:

The second thin film transistor (TFT) (T11), its grid input is from the actuation signal (ST (n-2)) of n-2 level GOA unit, drain electrode is connected respectively n-2 level horizontal scanning line (G(n-2) with source electrode) and this signal point (Q(n));

The 3rd thin film transistor (TFT) (T12), its grid connects n-1 level horizontal scanning line (G(n-1)), drain electrode is connected respectively this n-1 level horizontal scanning line (G(n-1) with source electrode) and this signal point (Q(n)).

2. the GOA circuit for flat pannel display as claimed in claim 1, is characterized in that, this drop-down holding circuit (300) comprising:

The 4th thin film transistor (TFT) (T32), its grid connects the first circuit point (P), drain electrode is connected respectively this n level horizontal scanning line (G(n) with source electrode) and input the first DC low-voltage (VSS);

The 5th thin film transistor (TFT) (T33), its grid connects second circuit point (K), drain electrode is connected respectively this n level horizontal scanning line (G(n) with source electrode) and this first DC low-voltage (VSS) of input;

The 6th thin film transistor (TFT) (T42), its grid connects this first circuit point (P), drain electrode is connected respectively this n-1 level horizontal scanning line (G(n-1) with source electrode) and this signal point (Q(n));

The 7th thin film transistor (TFT) (T43), its grid connects this second circuit point (K), drain electrode is connected respectively this n-1 level horizontal scanning line (G(n-1) with source electrode) and this signal point (Q(n));

The 8th thin film transistor (TFT) (T52), its grid connects this signal point (Q(n)), drain electrode is connected respectively this first circuit point (P) and this first DC low-voltage (VSS) of input with source electrode;

The 9th thin film transistor (TFT) (T62), its grid connects this signal point (Q(n)), drain electrode is connected respectively this second circuit point (K) and this first DC low-voltage (VSS) of input with source electrode;

The tenth thin film transistor (TFT) (T53), its grid is inputted the first clock signal (ECK), and drain electrode is inputted respectively this first clock signal (ECK) and is connected this first circuit point (P) with source electrode;

The 11 thin film transistor (TFT) (T54), its grid input second clock signal (EXCK), drain electrode is inputted respectively this first clock signal (ECK) and is connected this first circuit point (P) with source electrode;

The 12 thin film transistor (TFT) (T63), its grid is inputted this second clock signal (EXCK), and drain electrode is inputted respectively this second clock signal (EXCK) and is connected this second circuit point (K) with source electrode;

The 13 thin film transistor (TFT) (T64), its grid is inputted this first clock signal (ECK), and drain electrode is inputted respectively this second clock signal (EXCK) and is connected this second circuit point (K) with source electrode;

During work, the frequency of this first clock signal (ECK) and this second clock signal (EXCK) is lower than this n level clock signal (CK(n)), and this first circuit point (P) and this second circuit point (K) are alternately subject to this first clock signal (ECK) and the charging of this second clock signal (EXCK) and in noble potential.

3. the GOA circuit for flat pannel display as claimed in claim 1, it is characterized in that, this pull-up circuit (100) comprising: the 14 thin film transistor (TFT) (T21), its grid connects this signal point (Q(n)), drain electrode input respectively this n level clock signal (CK(n) with source electrode) be connected this n level horizontal scanning line (G(n)).

4. the GOA circuit for flat pannel display as claimed in claim 1, it is characterized in that, this pull-down circuit (200) comprising: the 15 thin film transistor (TFT) (T31), its grid connects n+2 level horizontal scanning line (G(n+2)), drain electrode is connected respectively this n level horizontal scanning line (G(n) with source electrode) and input this DC low-voltage (VSS); The 16 thin film transistor (TFT) (T41), its grid connects this n+2 level horizontal scanning line (G(n+2)), drain electrode is connected respectively this signal point (Q(n) with source electrode) and input this DC low-voltage (VSS).

5. the GOA circuit for flat pannel display as claimed in claim 1, is characterized in that, this n level clock signal (CK(n)) dutycycle be less than 50%.

6. the GOA circuit for flat pannel display as claimed in claim 5, is characterized in that, this n level clock signal (CK(n)) dutycycle be 40%.

7. the GOA circuit for flat pannel display as claimed in claim 1, is characterized in that, this first clock signal (ECK) is inputted a plurality of GOA unit of described cascade by public metal wire.

8. the GOA circuit for flat pannel display as claimed in claim 1, is characterized in that, this second clock signal (EXCK) is inputted a plurality of GOA unit of described cascade by public metal wire.

9. the GOA circuit for flat pannel display as claimed in claim 1, is characterized in that, this DC low-voltage (VSS) is inputted a plurality of GOA unit of described cascade by public metal wire.

10. a display device, is characterized in that, comprises the GOA circuit for flat pannel display as claimed in claim 1.